大别山典型燕山期侵入体中矿物成分特征及其地质意义

分析了大别造山带核部典型燕山期侵入体中的斜长石、黑云母和角闪石的化学成分和成因特点,并从矿物平衡角度讨论了典型侵入体岩石成因。结果表明：（１）石鼓尖侵入岩中,斜长石成分较稳定,共生角闪石和黑云母为岩浆平衡结晶的矿物;（２）天堂寨和九资河侵入岩中,部分斜长石和黑云母可能为深蚀残留矿物,角闪石属于火成岩区的新生矿物,可能为斜长石和黑云母发生融反应所形成;（３）三个侵入体的岩石均为岩浆成因。     

柔性承台下复合地基应力和沉降计算研究

柔性承台下复合地基的受力性状与刚性承台下复合地基有很大差别,常用的复合地基应力和沉降计算理论均基于刚性承台下复合地基,使计算值与实际值相差较大。利用Mindlin解与Boussinesq解联合求解柔性承台下复合地基的附加应力,可以得到与实际较符合的应力分布。利用Vesic小孔扩张理论计算桩体刺入柔性承台的量,并对分层总和法求得的沉降进行修正,可以得到与实测接近的沉降计算值。     

基于块体单元法的岩石边坡安全系数研究

岩石边坡因其结构面数量众多、块体系统及其滑动方式复杂,给危险块体组合的搜索及其安全系数计算带来很大困难。基于块体单元法,对岩石边坡中的危险块体组合搜索及其安全系数的计算方法进行了研究。首先,在块体元强度折减计算的成果下,根据屈服面贯通理论提出搜索危险块体组合的新方法;然后,对安全系数计算方法进行研究,建议在位移突变判据下采用双线性交叉法计算安全系数;最后,进行了单面、双面和多面滑动以及复杂块体系统的算例分析,并与刚体极限平衡法计算结果进行了对比。结果表明,由于块体单元法考虑了力与力矩的平衡及结构面上应力的非均匀分布,其计算结果更准确。该方法有望广泛应用于复杂岩石边坡稳定分析。     

海相辫状河三角洲沉积基准面旋回划分及砂体叠置样式分析：以西江W油田珠江组为例

西江W油田珠江组储层为一套海相辫状河三角洲前缘沉积砂体,内部结构复杂,微相类型多样。运用高分辨率层序地层学原理及测井频谱旋回分析技术,综合岩心、测井等资料,在西江W油田珠江组内部识别出5个长期和18个中期基准面旋回,搭建了精细层序地层格架。通过几何参数的统计和砂体发育规律的总结,在精细层序格架约束下,把辫状河三角洲砂体构型样式划分为孤立型、侧叠型、双向迁移型和堆叠型4种。研究表明基准面旋回变化控制了储层构型叠置样式和演化规律,不同的中期基准面旋回位置发育不同的构型样式,在中期基准面旋回上升早期或下降晚期,砂体以堆叠和侧叠为主,而中期基准面旋回上升晚期或下降早期则以双向迁移型和孤立型为主。构型分析成果有效指导了H11层剩余油的挖潜,并为海上油田三角洲储层构型研究提供了一定思路。     

复杂地形条件下地震速度提取方法及分析

通过对典型地形起伏的6个水平均匀层状介质理论地质模型的速度谱计算和分析,阐明了在复杂地形条件下用常规水平基准面方法提取叠加速度,不仅达不到地震勘探对速度精度的要求,而且产生假的纵、横向变速规律.证明了采用滑动基准面^[1]方法提取叠加速度,既可消除地形起伏的影响,又可满足地震勘探对速度精度的要求和如实反映地层速度.     

煤炭基地水污染研究理论体系探讨

以煤炭基地的水体为研究对象,以煤炭基地水污染研究理论体系的建立为研究重点,在分析中国能源形势和煤炭基地发展现状的基础上,通过查阅大量文献资料,并结合陕北煤炭基地实际情况,有针对性地提出煤炭基地水污染研究理论体系框架,具体分析了该体系五个组成部分的研究目的、研究内容和研究成果用途,在此基础上以陕北煤炭基地水污染问题为研究实例实践这一理论体系。结果表明：煤炭基地水污染研究理论体系由煤炭基地水污染背景条件研究、现状研究、机理研究、发展趋势研究和防治对策研究组成;陕北煤炭基地超过80%的地下水属于轻微污染和未污染,地表水存在一定程度的污染;窟野河大部分水化学组成从上游向下游呈先升高后降低的趋势;陕北煤炭基地未来地下水主要污染区分布在榆林市榆阳区、金鸡滩镇、神木县锦界、神木县城、大柳塔镇、府谷县城等;对原有污染严重的企业进行技术改造做到清洁生产,在企业相对集中的区域采取污水厂统一处理进行,新建企业必须进行污水处理设计,对生活污水采取土地渗滤或污水厂处理,固体废弃物要做无害化处理,农业生产中要求合理施肥。     

The Arinem Te‐Bearing Gold‐Silver‐Base Metal Deposit,West Java,Indonesia

The vein system in the Arinem area is a gold‐silver‐base metal deposit of Late Miocene (8.8–9.4 Ma) age located in the southwestern part of Java Island, Indonesia. The mineralization in the area is represented by the Arinem vein with a total length of about 5900 m, with a vertical extent up to 575 m, with other associated veins such as Bantarhuni and Halimun. The Arinem vein is hosted by andesitic tuff, breccia, and lava of the Oligocene–Middle Miocene Jampang Formation (23–11.6 Ma) and overlain unconformably by Pliocene–Pleistocene volcanic rocks composed of andesitic‐basaltic tuff, tuff breccia and lavas. The inferred reserve is approximately 2 million tons at 5.7 g t^?1 gold and 41.5 g t^?1 silver at a cut‐off of 4 g t^?1 Au, which equates to approximately 12.5t of Au and 91.4t of Ag. The ore mineral assemblage of the Arinem vein consists of sphalerite, galena, chalcopyrite, pyrite, marcasite, and arsenopyrite with small amounts of pyrrhotite, argentite, electrum, bornite, hessite, tetradymite, altaite, petzite, stutzite, hematite, enargite, tennantite, chalcocite, and covellite. These ore minerals occur in quartz with colloform, crustiform, comb, vuggy, massive, brecciated, bladed and calcedonic textures and sulfide veins. A pervasive quartz–illite–pyrite alteration zone encloses the quartz and sulfide veins and is associated with veinlets of quartz–calcite–pyrite. This alteration zone is enveloped by smectite–illite–kaolinite–quartz–pyrite alteration, which grades into a chlorite–smectite–kaolinite–calcite–pyrite zone. Early stage mineralization (stage I) of vuggy–massive–banded crystalline quartz‐sulfide was followed by middle stage (stage II) of banded–brecciated–massive sulfide‐quartz and then by last stage (stage III) of massive‐crystalline barren quartz. The temperature of the mineralization, estimated from fluid inclusion microthermometry in quartz ranges from 157 to 325°C, whereas the temperatures indicated by fluid inclusions from sphalerite and calcite range from 153 to 218 and 140 to 217°C, respectively. The mineralizing fluid is dilute, with a salinity <4.3 wt% NaCl equiv. The ore‐mineral assemblage and paragenesis of the Arinem vein is characteristically of a low sulfidation epithermal system with indication of high sulfidation overprinted at stage II. Boiling is probably the main control for the gold solubility and precipitation of gold occurred during cooling in stage I mineralization.     

High-pressure Partial Melting of Mafic Lithologies in the Mantle

We review experimental phase equilibria associated with partialmelting of mafic lithologies (pyroxenites) at high pressuresto reveal systematic relationships between bulk compositionsof pyroxenite and their melting relations. An important aspectof pyroxenite phase equilibria is the existence of the garnet–pyroxenethermal divide, defined by the enstatite–Ca-Tschermakspyroxene–diopside plane in CaO–MgO–Al₂O₃–SiO₂projections. This divide appears at pressures above 2 GPa inthe natural system where garnet and pyroxenes are the principalresidual phases in pyroxenites. Bulk compositions that resideon either side of the divide have distinct phase assemblagesfrom subsolidus to liquidus and produce distinct types of partialmelt ranging from strongly nepheline-normative to quartz-normativecompositions. Solidus and liquidus locations are little affectedby the location of natural pyroxenite compositions relativeto the thermal divide and are instead controlled chiefly bybulk alkali contents and Mg-numbers. Changes in phase volumesof residual minerals also influence partial melt compositions.If olivine is absent during partial melting, expansion of thephase volume of garnet relative to clinopyroxene with increasingpressure produces liquids with high Ca/Al and low MgO comparedwith garnet peridotite-derived partial melts. KEY WORDS: experimental petrology; mantle heterogeneity; partial melting; phase equilibrium; pyroxenite     

Prospector II: Towards a knowledge base for mineral deposits

What began in the mid-seventies as a research effort in designing an expert system to aid geologists in exploring for hidden mineral deposits has in the late eighties become a full-sized knowledge-based system to aid geologists in conducting regional mineral resource assessments. Prospector II, the successor to Prospector, is interactive-graphics oriented, flexible in its representation of mineral deposit models, and suited to regional mineral resource assessment. In Prospector II, the geologist enters the findings for an area, selects the deposit models or examples of mineral deposits for consideration, and the program compares the findings with the models or the examples selected, noting the similarities, differences, and missing information. The models or the examples selected are ranked according to scores that are based on the comparisons with the findings. Findings can be reassessed and the process repeated if necessary. The results provide the geologist with a rationale for identifying those mineral deposit types that the geology of an area permits. In future, Prospector II can assist in the creation of new models used in regional mineral resource assessment and in striving toward an ultimate classification of mineral deposits.